Syntheses, Crystal Structures and DNA-Binding Properties of Cu(Ⅱ)/Ni(Ⅱ) Complexes with Acylhydrazone Ligand Bearing Pyrazine Unit

Wan-Wan WANG Yuan WANG Ling ZHANG Yu-Fei SONG Wei-Na WU Zhong CHEN

Citation:  WANG Wan-Wan, WANG Yuan, ZHANG Ling, SONG Yu-Fei, WU Wei-Na, CHEN Zhong. Syntheses, Crystal Structures and DNA-Binding Properties of Cu(Ⅱ)/Ni(Ⅱ) Complexes with Acylhydrazone Ligand Bearing Pyrazine Unit[J]. Chinese Journal of Inorganic Chemistry, 2019, 35(3): 563-568. doi: 10.11862/CJIC.2019.037 shu

吡嗪酰腙配体Cu(Ⅱ)/Ni(Ⅱ)配合物的合成、晶体结构及DNA结合性质

    通讯作者: 王元, wangyuan08@hpu.edu.cn
    吴伟娜, wuwn08@hpu.edu.cn
  • 基金项目:

    江西省教育厅科学技术研究项目 GJJ170665

    河南理工大学校内基金 T2018-3

    国家自然科学基金 21001040

    河南省自然科学基金 162300410011

    河南省教育厅高等学校重点科研基金 19A150001

    江西省自然科学基金 20181BAB206011

    国家自然科学基金(No.21001040),河南省自然科学基金(No.182300410183,162300410011),江西省自然科学基金(No.20181BAB206011),河南省教育厅高等学校重点科研基金(No.19A150001),江西省教育厅科学技术研究项目(No.GJJ170665),河南理工大学校内基金(No.T2018-3,J2015-4)和江西科技师范大学校内基金(No.2015QNBJRC006)资助

    河南省自然科学基金 182300410183

    河南理工大学校内基金 J2015-4

    江西科技师范大学校内基金 2015QNBJRC006

摘要: 合成并通过单晶衍射、元素分析及红外光谱表征了配合物[Ni(L)(HL)](SO40.5·3CH3OH(1)和[Cu2(L)2SO4]·1.5CH3OH(2)的结构(HL为3-甲基-2-乙酰吡嗪苯甲酰腙)。单晶衍射实验结果表明,在配合物1中,Ni(Ⅱ)中心离子与2个酰肼配体的[ONN]配位原子组配位,形成扭曲的八面体配位构型;2的最小非对称单元中含有1个独立的双核Cu(Ⅱ)配合物分子,它的2个Cu(Ⅱ)中心由2个酰肼配体中的2个O原子桥联。每个Cu(Ⅱ)离子还与L-配体中的2个氮原子和η2-SO42-阴离子中的1个O原子配位,拥有扭曲的四方锥配位构型。此外,荧光光谱表明配合物和DNA的结合能力强于配体。

English

  • Schiff bases and their metal complexes have been widely used in medical fields such as anticancer, antibacterial, and antiviral drugs[1-2]. Generally, the presence of a heterocyclic ring in the synthesized Schiff bases plays a major role in extending their pharmacological properties[3]. Particularly, pyrazine-containing thiosemicarbazone has been extensively investigated as potential anticancer agents[4], because pyrazine is a vital nitrogen heterocyclic compound with various biological activities and a key structural unit for the drug design[4-6]. However, acylhydrazones bearing pyrazine unit, as their structural analogs, received much less attention[4, 7-8].

    Our previous work has showed that 2-acetopyrazine benzoylacylhydrazone could form stable complexes with transition metal ions, such as Cu(Ⅱ), Ni(Ⅱ) and Zn(Ⅱ)[5]. It is noted that the biological activities of acylhydrazones often show a high depend-ence on their substituent[9]. In this regard, we chose 2-aceto-3-methylpyrazine as the starting material for the formation of benzoylacylhydrazone ligand HL (Scheme 1). In this paper, the structures and DNA-binding properties of its Ni(Ⅱ)/Cu(Ⅱ) complexes have been discussed in detail.

    Scheme 1

    Scheme 1.  Synthetic route of HL

    Solvents and starting materials for synthesis were purchased commercially and used as received. Elemental analysis was carried out on an Elemental Vario EL analyzer. The IR spectra (ν=4 000~400 cm-1) were determined by the KBr pressed disc method on a Bruker V70 FT-IR spectrophotometer. 1H NMR spectra of HL was acquired with Bruker AV400 NMR instru-ment in DMSO-d6 solution with TMS as internal standard. The UV spectra were recorded on a Purkinje General TU-1800 spectrophotometer. The interactions between the complexes and ct-DNA are measured by using literature method[5] via emission spectra on a Varian CARY Eclipse spectrophotometer.

    As shown in Scheme 1, the ligand HL was produced by condensation of 2-aceto-3-methylpyrazine (1.36 g, 0.01 mol) and benzoylhydrazide (1.36 g, 0.01 mol) in ethanol solution (30 mL) with continuous stirring at room temperature for 3 h. Yield: 2.08 g (82%). Elemental analysis Calcd. for C14H14N4O(%): C: 66.13; H: 5.55; N: 22.03. Found(%): C: 66.28; H: 5.44; N: 21.99. FT-IR (cm-1): ν(C=O) 1 685, ν(C=N)imine 1 582, ν(C=N)pyrazine 1 542. 1H NMR (400 MHz, DMSO-d6): δ 10.97 (1H, s, NH), 8.52 (2H, s, pyrazine-H), 7.91 (2H) and 7.53~7.60 (3H) for phenyl-H, 2.80 (3H, s, CH3), 2.43 (3H, s, CH3).

    The complexes 1 and 2 were generated by reaction of the ligand HL (5 mmol) with equimolar of NiSO4 or CuSO4 in methanol solution (10 mL) at room temperature for 1 h. Crystals suitable for X-ray diffraction analysis were obtained by evaporating the corresponding reaction solutions at room temperature.

    1: Brown blocks. Anal. Calcd. for C31H39N8O7S0.5Ni(%): C: 52.41; H: 5.53; N: 15.77. Found(%): C: 52.30; H: 5.64; N: 15.54. FT-IR (cm-1): ν(C=O) 1 654, ν(C=N) 1 562, ν(C=N)pyrazine 1 532.

    2: Green blocks. Anal. Calcd. for C29.5H32N8O7.5 SCu2(%): C: 45.55; H: 4.15; N: 14.41. Found (%): C: 45.41; H: 4.28; N: 14.32. FT-IR (cm-1): ν(C=O) 1 652, ν(C=N) 1 560, ν(C=N)pyrazine 1 535.

    The X-ray diffraction measurement for 1 (size: 0.20 mm×0.20 mm×0.20 mm) and 2 (size: 0.15 mm×0.14 mm×0.12 mm) were performed on a Bruker SMART APEX Ⅱ CCD diffractometer equipped with a graphite monochromatized Mo radiation (λ=0.071 073 nm) using φ-ω scan mode. Semi-empirical absorption correction was applied to the intensity data using the SADABS program[10]. The structures were solved by direct methods and refined by full matrix least-square on F2 using the SHELXTL-97 program[11]. All non-hydrogen atoms were refined anisotropically. The H atoms of disordered methanol molecule (occupancy value of each atom being 0.5) in 2 were not added. All the other H atoms were positioned geometrically and refined using a riding model. Details of the crystal parameters, data collection and refinements for 1 and 2 are summarized in Table 1.

    Table 1

    Table 1.  Crystal data and structure refinement for complexes 1 and 2
    下载: 导出CSV
    1 2
    Empirical formula C31H39N8O7S0.5Ni C29.5H32N8O7.5SCu2
    Formula weight 710.44 777.77
    T / K 296(2) 293(2)
    Crystal system Monoclinic Triclinic
    Space group C2/c P1
    a / nm 2.066 0(3) 1.070 2(5)
    b / nm 1.451 20(17) 1.172 3(6)
    c / nm 2.273 1(3) 1.420 9(6)
    α / (°) 71.701(8)
    β / (°) 104.518(2) 73.328(7)
    γ / (°) 72.022(7)
    V / nm3 6.597 6(15) 1.573 8(13)
    Z 8 2
    Dc / (g·cm-3) 1.431 1.641
    Absorption coefficient / mm-1 0.679 1.481
    F(000) 2 984 798.0
    Reflection collected 16 533 8 031
    Unique reflection 5 802 5 486
    Rint 0.026 0 0.056 2
    Goodness-of-fit (GOF) on F2 1.037 1.070
    R indices [I > 2σ(I)] R1=0.046 9, wR2=0.130 1 R1=0.050 1, wR2=0.139 8
    R indices (all data) R1=0.055 6, wR2=0.137 7 R1=0.066 9, wR2=0.151 0

    CCDC 1876785: 1; 1876789: 2.

    Diamond drawings of complexes 1 and 2 are shown in Fig. 1. Selected bond distances and angles are listed in Table 2. As shown in Fig. 1a, the asymm-etric unit of 1 contains one discrete cationic Ni(Ⅱ) ion, a half of sulfate anions for charge balance, and three lattice methanol molecules. The center Ni(Ⅱ) ion with a distorted octahedron geometry is coordinated by two acylhydrazones with [ONN] donor set. It should be noted that one of the acylhydrazone ligands is neutral, since the bond length of C8-O1 (0.123 3(3) nm) is clearly shorter than that of C22-O2 (0.126 5(4) nm). In the solid state, intermolecular N-H…O (N4-H4…O4, with D…A distance being 0.270 0(3) nm, D-H…A angle being 139.6°) and O-H…O (O7-H7…O6, with D…A distance being 0.278 0(12) nm, D-H…A angle being 159.6°; O5-H5…O3, with D…A distance being 0.296 1(8) nm, D-H…A angle being 118.8°; O6-H6…O4, with D…A distance being 0.281 5(7) nm, D-H…A angle being 125.0°) hydrogen bonds are helpful to stabilize the crystal structure (Fig. 1a).

    Figure 1

    Figure 1.  Diamond drawings of 1 (a) and 2 (b) with 10% thermal ellipsoids

    Hydrogen bonds shown in dashed line; H atoms of C-H bonds are omitted for clarity; Symmetry codes: i-x, y, 1.5-z; ii 3-x, -y, -z

    Table 2

    Table 2.  Selected bond lengths (nm) and angles (°) in complexes 1 and 2
    下载: 导出CSV
    1
    Ni1-N1 0.207 5(3) Ni1-N3 0.199 0(2) Ni1-O1 0.209 9(2)
    Ni1-N5 0.207 4(2) Ni1-N7 0.195 2(2) Ni1-O2 0.205 3(2)
    N3-Ni1-N1 76.53(9) N3-Ni1-N5 100.20(10) N5-Ni1-N1 94.21(9)
    N7-Ni1-N1 101.88(10) N7-Ni1-N3 177.60(9) N7-Ni1-N5 78.06(9)
    N1-Ni1-O1 153.44(9) N3-Ni1-O1 77.14(8) N3-Ni1-O2 103.90(9)
    N5-Ni1-O1 93.79(9) N7-Ni1-O1 104.54(9) N7-Ni1-O2 77.94(9)
    O2-Ni1-N1 94.18(9) O2-Ni1-N5 155.72(9) O2-Ni1-O1 88.76(8)
    2
    Cu1-N1 0.198 7(3) Cu1-N3 0.190 3(3) Cu2-N5 0.199 0(4)
    Cu2-N7 0.189 7(4) Cu1-O1 0.195 6(3) Cu1-O2 0.255 8(3)
    Cu1-O3 0.189 4(3) Cu2-O1 0.258 3(3) Cu2-O2 0.195 4(3)
    Cu2-O4 0.188 3(3)
    N1-Cu1-O2 97.19(12) N3-Cu1-N1 79.85(14) N5-Cu2-O1 96.39(12)
    N3-Cu1-O1 80.86(12) N3-Cu1-O2 91.74(12) N7-Cu2-O2 80.30(14)
    N7-Cu2-N5 79.98(16) N7-Cu2-O1 91.64(13) O2-Cu2-N5 160.26(14)
    O1-Cu1-N1 160.70(13) O1-Cu1-O2 84.03(11) O3-Cu1-N3 171.81(14)
    O2-Cu2-O1 83.39(11) O3-Cu1-N1 101.01(14) O4-Cu2-N5 97.72(15)
    O3-Cu1-O1 98.00(13) O3-Cu1-O2 96.21(12) O4-Cu2-O2 102.01(14)
    O4-Cu2-N7 175.98(14) O4-Cu2-O1 91.89(13)

    Complex 2 crystallizes in the triclinic space group P1 with one discrete dimeric Cu(Ⅱ) unit in the unit cell. As illustrated in Fig. 1b, two Cu(Ⅱ) ions of the dimer are separated by 0.317 4 nm and doubly bridged by two O atoms from two acylhydrazone ligands to form a nearly planar four-membered Cu2O2 core (r.m.s. deviation: 0.030 15 nm). Each of the Cu(Ⅱ) ions is also coordinated by two N atoms from one L- ligand (bond length of C8-O1 and C22-O2 are 0.128 8(5) and 0.129 2(5) nm, respectively) and one O atom from the η2-SO42- at the outer axial sites, giving a distorted square pyramid coordination geometry (τ=0.185 and 0.262 for Cu1 and Cu2, respe-ctively)[12]. The O-H…O (O7-H7…O5, with D…A distance being 0.272 4(7) nm, D-H…A angle being 168.3°; O8…O7, with D…A distance being 0.257 4 nm) hydrogen bonds are also present in the crystal (Fig. 1b).

    The FT-IR spectral regions for both complexes were more or less similar due to the similar coor-dination modes of the ligands. The ν(C=O), ν(C=N)imine and ν(C=N)pyrazine bands were at 1 663, 1 578 and 1 559 cm-1, respectively. They shifted to lower frequency values in the IR spectra of complexes, indicating that the carbonyl O, imine N and pyrazine N atoms take part in the coordination[5]. It is in accordance with the crystal structure study.

    The UV spectra of the ligand HL, 1 and 2 in CH3OH solution (10 μmol·L-1) were measured at room temperature (Fig. 2). The spectra of HL featured two main band at around 230 nm (ε=10 950 L·mol-1·cm-1) and 290 nm (ε=15 423 L·mol-1·cm-1), which could be assigned to characteristic π-π* transition of pyrazine and imine units, respectively[13]. In the spectrum of complex 1, these two bonds red-shifted to 256 nm (ε=12 832 L·mol-1·cm-1) and 306 nm (ε=15 191 L·mol-1 ·cm-1), respectively. By contrast, two bands of the ligand were merged into one at 271 nm (ε=17 968 L·mol-1·cm-1) in the spectrum of complex 2. Moreover, new peaks at 400 nm (ε=15 314 L·mol-1·cm-1) and 401 nm (ε=12 955 L·mol-1·cm-1) were observed in the spectra of complexes 1 and 2, respectively, primarily due to the ligand-to-metal charge transfer (LMCT)[14]. This indicates that an extended conjugation forms in anionic ligand after complexation.

    Figure 2

    Figure 2.  UV spectra of the ligand HL, complexes 1 and 2 in CH3OH solution at room temperature

    It is well known that EB can intercalate nonspecifically into DNA, which causes it to fluoresce strongly. Competitive binding of other drugs to DNA and EB will result in displacement of bound EB and a decrease in the fluorescence intensity[14-15]. The effects of the ligand and complexes on the fluorescence spectra of EB-DNA system are presented in Fig. 3. The fluorescence intensities of EB bound to ct-DNA at about 600 nm showed remarkable decreasing trends with the increasing concentration of the tested compounds, indicating that some EB molecules are released into solution after the exchange with the compounds. The quenching of EB bound to DNA by the compounds is in agreement with the linear Stern-Volmer equation: I0/I=1+Ksqr[14-15], where I0 and I represent the fluorescence intensities in the absence and presence of quencher, respectively, Ksq is the linear Stern-Volmer quenching constant, r is the ratio of the concentration of quencher and DNA. In the quenching plots of I0/I versus r, Ksq values are given by the slopes. The Ksq values were 0.545, 1.823 and 1.236 for the ligand HL, complexes 1 and 2, respe-ctively. The results indicate that interaction of the complexes to DNA is stronger than that of the ligand HL, because the complexes have higher rigidity to bind the base pairs along DNA, thus increasing their binding abilities.

    Figure 3

    Figure 3.  Emission spectra of EB-DNA system in the absence and presence of ligand HL (a), complexes 1 (b) and 2 (c)

    Arrow shows the fluorescence intensities change of EB-DNA system upon increasing tested compound concentration; Inset: plot of I0/I versus r

    Two complexes with a pyrazine-containing benzoylhydrazone ligand were prepared and chara-cterized by single-crystal X-ray crystallography. In complex 1, the center Ni(Ⅱ) ion is surrounded by two acylhydrazones with [ONN] donor set, giving a distorted octahedron geometry. By contrast, complex 2 contains one discrete dimeric Cu(Ⅱ) unit in the unit cell. Moreover, the fluorescence spectra indicated that the interaction of the complexes to DNA is stronger than that of the ligand HL. Further research is needed to better determine the relationship between structures and activities.

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      毛盼东, 赵晓雷, 邵志鹏, 等.无机化学学报, 2017, 33(5):890-896 http://www.wjhxxb.cn/wjhxxbcn/ch/reader/view_abstract.aspx?flag=1&file_no=20170522&journal_id=wjhxxbcnMAO Pan-dong, ZHAO Xiao-Lei, SHAO Zhi-Peng, et al. Chinese J. Inorg. Chem., 2017, 33(5):890-896 http://www.wjhxxb.cn/wjhxxbcn/ch/reader/view_abstract.aspx?flag=1&file_no=20170522&journal_id=wjhxxbcn

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  • Scheme 1  Synthetic route of HL

    Figure 1  Diamond drawings of 1 (a) and 2 (b) with 10% thermal ellipsoids

    Hydrogen bonds shown in dashed line; H atoms of C-H bonds are omitted for clarity; Symmetry codes: i-x, y, 1.5-z; ii 3-x, -y, -z

    Figure 2  UV spectra of the ligand HL, complexes 1 and 2 in CH3OH solution at room temperature

    Figure 3  Emission spectra of EB-DNA system in the absence and presence of ligand HL (a), complexes 1 (b) and 2 (c)

    Arrow shows the fluorescence intensities change of EB-DNA system upon increasing tested compound concentration; Inset: plot of I0/I versus r

    Table 1.  Crystal data and structure refinement for complexes 1 and 2

    1 2
    Empirical formula C31H39N8O7S0.5Ni C29.5H32N8O7.5SCu2
    Formula weight 710.44 777.77
    T / K 296(2) 293(2)
    Crystal system Monoclinic Triclinic
    Space group C2/c P1
    a / nm 2.066 0(3) 1.070 2(5)
    b / nm 1.451 20(17) 1.172 3(6)
    c / nm 2.273 1(3) 1.420 9(6)
    α / (°) 71.701(8)
    β / (°) 104.518(2) 73.328(7)
    γ / (°) 72.022(7)
    V / nm3 6.597 6(15) 1.573 8(13)
    Z 8 2
    Dc / (g·cm-3) 1.431 1.641
    Absorption coefficient / mm-1 0.679 1.481
    F(000) 2 984 798.0
    Reflection collected 16 533 8 031
    Unique reflection 5 802 5 486
    Rint 0.026 0 0.056 2
    Goodness-of-fit (GOF) on F2 1.037 1.070
    R indices [I > 2σ(I)] R1=0.046 9, wR2=0.130 1 R1=0.050 1, wR2=0.139 8
    R indices (all data) R1=0.055 6, wR2=0.137 7 R1=0.066 9, wR2=0.151 0
    下载: 导出CSV

    Table 2.  Selected bond lengths (nm) and angles (°) in complexes 1 and 2

    1
    Ni1-N1 0.207 5(3) Ni1-N3 0.199 0(2) Ni1-O1 0.209 9(2)
    Ni1-N5 0.207 4(2) Ni1-N7 0.195 2(2) Ni1-O2 0.205 3(2)
    N3-Ni1-N1 76.53(9) N3-Ni1-N5 100.20(10) N5-Ni1-N1 94.21(9)
    N7-Ni1-N1 101.88(10) N7-Ni1-N3 177.60(9) N7-Ni1-N5 78.06(9)
    N1-Ni1-O1 153.44(9) N3-Ni1-O1 77.14(8) N3-Ni1-O2 103.90(9)
    N5-Ni1-O1 93.79(9) N7-Ni1-O1 104.54(9) N7-Ni1-O2 77.94(9)
    O2-Ni1-N1 94.18(9) O2-Ni1-N5 155.72(9) O2-Ni1-O1 88.76(8)
    2
    Cu1-N1 0.198 7(3) Cu1-N3 0.190 3(3) Cu2-N5 0.199 0(4)
    Cu2-N7 0.189 7(4) Cu1-O1 0.195 6(3) Cu1-O2 0.255 8(3)
    Cu1-O3 0.189 4(3) Cu2-O1 0.258 3(3) Cu2-O2 0.195 4(3)
    Cu2-O4 0.188 3(3)
    N1-Cu1-O2 97.19(12) N3-Cu1-N1 79.85(14) N5-Cu2-O1 96.39(12)
    N3-Cu1-O1 80.86(12) N3-Cu1-O2 91.74(12) N7-Cu2-O2 80.30(14)
    N7-Cu2-N5 79.98(16) N7-Cu2-O1 91.64(13) O2-Cu2-N5 160.26(14)
    O1-Cu1-N1 160.70(13) O1-Cu1-O2 84.03(11) O3-Cu1-N3 171.81(14)
    O2-Cu2-O1 83.39(11) O3-Cu1-N1 101.01(14) O4-Cu2-N5 97.72(15)
    O3-Cu1-O1 98.00(13) O3-Cu1-O2 96.21(12) O4-Cu2-O2 102.01(14)
    O4-Cu2-N7 175.98(14) O4-Cu2-O1 91.89(13)
    下载: 导出CSV
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  • 发布日期:  2019-03-10
  • 收稿日期:  2018-11-05
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